about
Excision repair cross-complementing rodent repair deficiency, complementation group 2Excision repair cross-complementing rodent repair deficiency, complementation group 3COP9 signalosome subunit 2Peptidylprolyl isomerase ECOP9 signalosome subunit 8COP9 signalosome subunit 7BXPA binding protein 2ISY1-RAB43 readthroughAquarius intron-binding spliceosomal factorERCC excision repair 6, chromatin remodeling factorDamage specific DNA binding protein 1Cyclin HCOP9 signalosome subunit 6RNA polymerase II, I and III subunit LReplication protein A1Ubiquitin specific peptidase 7COP9 signalosome subunit 5Pre-mRNA processing factor 19ERCC excision repair 1, endonuclease non-catalytic subunitG protein pathway suppressor 1COP9 signalosome subunit 4COP9 signalosome subunit 7AUbiquitin CXPA, DNA damage recognition and repair factorERCC excision repair 5, endonucleaseERCC excision repair 8, CSA ubiquitin ligase complex subunitCullin 4ACullin 4BUbiquitin BMNAT1 component of CDK activating kinaseReplication protein A2RNA polymerase II subunit CRing-box 1DNA ligase 1Replication factor C subunit 2DNA ligase 3DNA polymerase delta 1, catalytic subunitDNA polymerase delta 2, accessory subunitDNA polymerase delta 3, accessory subunitDNA polymerase delta 4, accessory subunit
P682
The ATPase domain but not the acidic region of Cockayne syndrome group B gene product is essential for DNA repairMutations in UVSSA cause UV-sensitive syndrome and destabilize ERCC6 in transcription-coupled DNA repairMolecular mechanism of nucleotide excision repair.How nucleotide excision repair protects against cancer.Schizosaccharomyces pombe Ddb1 recruits substrate-specific adaptor proteins through a novel protein motif, the DDB-box.
P921
Q14908100-E5FE5AF6-8B7F-405B-9AA3-B38F16B203BDQ14916140-CDA57D05-FE9F-4919-87BE-383437F8041CQ14916140-DE60F06B-5A01-4FE1-A436-FF7076406A86Q21102196-EF567263-2691-4D47-A3D8-3BCACFB8605BQ21103456-D1C4A8C0-6CBC-442C-92AE-0C447B4CB0C9Q21105704-5824CDBD-09F9-4DA2-8AC6-B46A377A041AQ21105706-BB88420F-42D1-4815-B2C8-2C875891EA86Q21105807-4C876EF5-37C5-4BE9-A678-6EA5ADAA220DQ21105813-BBDA428E-DB89-4412-914C-5B062EF1F454Q21106449-EC937A31-113C-4B5A-932C-466B7CEB56C7Q21106758-3844D832-2D1D-4079-9535-F743153A8088Q21108214-0C3504E4-B5AB-4B2B-8DC3-419B83CE3182Q21109264-480121A5-890A-43C7-B60A-617A267B091FQ21109321-2E593E10-3DFA-433B-B7E8-9CA4B87D21E6Q21109488-385086BD-BC1D-4E9D-A9AF-A1C73AD21B6EQ21109589-5B145C00-AF76-44BB-AE83-F9B8B43A242BQ21109614-8420062E-4A28-44F1-8E78-E76A20BF571EQ21109641-FD8BB2EC-BD3B-4E43-ACA4-E1F064963DF2Q21109719-6EF83F70-8325-4725-8402-90D9955846BAQ21110095-8ADDE690-BAA8-4203-A894-E29CF038F6AEQ21110805-8AA2FA0E-BFDE-4D9C-9FAC-9F33E336CFABQ21110809-46D81CB0-DE31-4331-8912-3AAD7B0DEFE1Q21110810-5CE484C7-9322-4025-BCAE-5527BBEEDB07Q21111827-F687FEF8-2DAA-4987-B774-050EC52924A6Q21112332-43FEB51E-C00A-4919-80F5-07F4F7F99ADCQ21112337-5783F712-8278-4920-B7AC-1E0113D2FCEAQ21112346-123EACCB-1E7D-48B3-9D74-F518C4C2E107Q21112346-774CF82D-762A-4748-8F76-2D13AA60E7C2Q21112346-8A1B68FC-8B37-4250-B648-2E2C2AF53687Q21112920-03F2C510-6B1B-473D-9640-02D693D0CF30Q21112921-948A9FD1-BF6D-4DC8-94D6-EB12D0A05061Q21112968-D09DE06E-868F-42E6-B0F7-8F6AC074777AQ21114920-7DB2CE15-C790-465A-98F8-E397621A9742Q21115044-4DB1185A-22EF-45F6-AC87-A784AE6280AAQ21116809-0EFADEE3-C8FF-4D84-A90E-25B2A72B3DCFQ21117428-A76CF3E8-F29A-4D22-A6E1-BA85F1A8C84FQ21117820-1D4EE497-BBBC-4ECB-84BA-828A70164453Q21117901-B4BCC7ED-ED6A-483B-BA0E-E08607FAECBDQ21117954-8F4289A8-D88B-4A04-9AE6-4B44CB2938C4Q21117980-FF0291FC-5C87-4727-BF75-8A104059B3C6
P682
description
The nucleotide-excision repair ...... s required for the recognition
@en
biologisch proces
@nl
name
transcription-coupled nucleotide-excision repair
@en
type
label
transcription-coupled nucleotide-excision repair
@en
altLabel
GO:0006283
@en
TC-NER
@en
transcription-coupled NER
@en
transcription-coupled repair
@en
prefLabel
transcription-coupled nucleotide-excision repair
@en
P2888
P686
GO:0006283